use std::mem::take;

use crate::asm::*;
use crate::asm::x86_64::*;
use crate::codegen::CodePtr;
use crate::cruby::*;
use crate::backend::ir::*;
use crate::options::*;
use crate::utils::*;

// Use the x86 register type for this platform
pub type Reg = X86Reg;

// Callee-saved registers
pub const _CFP: Opnd = Opnd::Reg(R13_REG);
pub const _EC: Opnd = Opnd::Reg(R12_REG);
pub const _SP: Opnd = Opnd::Reg(RBX_REG);

// C argument registers on this platform
pub const _C_ARG_OPNDS: [Opnd; 6] = [
    Opnd::Reg(RDI_REG),
    Opnd::Reg(RSI_REG),
    Opnd::Reg(RDX_REG),
    Opnd::Reg(RCX_REG),
    Opnd::Reg(R8_REG),
    Opnd::Reg(R9_REG)
];

// C return value register on this platform
pub const C_RET_REG: Reg = RAX_REG;
pub const _C_RET_OPND: Opnd = Opnd::Reg(RAX_REG);

impl CodeBlock {
    // The number of bytes that are generated by jmp_ptr
    pub fn jmp_ptr_bytes(&self) -> usize { 5 }
}

/// Map Opnd to X86Opnd
impl From<Opnd> for X86Opnd {
    fn from(opnd: Opnd) -> Self {
        match opnd {
            // NOTE: these operand types need to be lowered first
            //Value(VALUE),       // Immediate Ruby value, may be GC'd, movable
            //InsnOut(usize),     // Output of a preceding instruction in this block

            Opnd::InsnOut{..} => panic!("InsnOut operand made it past register allocation"),

            Opnd::UImm(val) => uimm_opnd(val),
            Opnd::Imm(val) => imm_opnd(val),
            Opnd::Value(VALUE(uimm)) => uimm_opnd(uimm as u64),

            // General-purpose register
            Opnd::Reg(reg) => X86Opnd::Reg(reg),

            // Memory operand with displacement
            Opnd::Mem(Mem{ base: MemBase::Reg(reg_no), num_bits, disp }) => {
                let reg = X86Reg {
                    reg_no,
                    num_bits: 64,
                    reg_type: RegType::GP
                };

                mem_opnd(num_bits, X86Opnd::Reg(reg), disp)
            }

            Opnd::None => panic!(
                "Attempted to lower an Opnd::None. This often happens when an out operand was not allocated for an instruction because the output of the instruction was not used. Please ensure you are using the output."
            ),

            _ => panic!("unsupported x86 operand type")
        }
    }
}

/// Also implement going from a reference to an operand for convenience.
impl From<&Opnd> for X86Opnd {
    fn from(opnd: &Opnd) -> Self {
        X86Opnd::from(*opnd)
    }
}

/// List of registers that can be used for stack temps and locals.
pub static TEMP_REGS: [Reg; 5] = [RSI_REG, RDI_REG, R8_REG, R9_REG, R10_REG];

impl Assembler
{
    // A special scratch register for intermediate processing.
    // This register is caller-saved (so we don't have to save it before using it)
    pub const SCRATCH_REG: Reg = R11_REG;
    const SCRATCH0: X86Opnd = X86Opnd::Reg(Assembler::SCRATCH_REG);


    /// Get the list of registers from which we can allocate on this platform
    pub fn get_alloc_regs() -> Vec<Reg>
    {
        vec![
            RAX_REG,
            RCX_REG,
            RDX_REG,
        ]
    }

    /// Get a list of all of the caller-save registers
    pub fn get_caller_save_regs() -> Vec<Reg> {
        vec![RAX_REG, RCX_REG, RDX_REG, RSI_REG, RDI_REG, R8_REG, R9_REG, R10_REG, R11_REG]
    }

    // These are the callee-saved registers in the x86-64 SysV ABI
    // RBX, RSP, RBP, and R12–R15

    /// Split IR instructions for the x86 platform
    fn x86_split(mut self) -> Assembler
    {
        let live_ranges: Vec<usize> = take(&mut self.live_ranges);
        let mut asm = Assembler::new_with_label_names(take(&mut self.label_names), take(&mut self.side_exits), self.num_locals);
        let mut iterator = self.into_draining_iter();

        while let Some((index, mut insn)) = iterator.next_unmapped() {
            // When we're iterating through the instructions with x86_split, we
            // need to know the previous live ranges in order to tell if a
            // register lasts beyond the current instruction. So instead of
            // using next_mapped, we call next_unmapped. When you're using the
            // next_unmapped API, you need to make sure that you map each
            // operand that could reference an old index, which means both
            // Opnd::InsnOut operands and Opnd::Mem operands with a base of
            // MemBase::InsnOut.
            //
            // You need to ensure that you only map it _once_, because otherwise
            // you'll end up mapping an incorrect index which could end up being
            // out of bounds of the old set of indices.
            //
            // We handle all of that mapping here to ensure that it's only
            // mapped once. We also handle loading Opnd::Value operands into
            // registers here so that all mapping happens in one place. We load
            // Opnd::Value operands into registers here because:
            //
            //   - Most instructions can't be encoded with 64-bit immediates.
            //   - We look for Op::Load specifically when emitting to keep GC'ed
            //     VALUEs alive. This is a sort of canonicalization.
            let mut unmapped_opnds: Vec<Opnd> = vec![];

            let is_load = matches!(insn, Insn::Load { .. } | Insn::LoadInto { .. });
            let mut opnd_iter = insn.opnd_iter_mut();

            while let Some(opnd) = opnd_iter.next() {
                if let Opnd::Stack { .. } = opnd {
                    *opnd = asm.lower_stack_opnd(opnd);
                }
                unmapped_opnds.push(*opnd);

                *opnd = match opnd {
                    Opnd::Value(value) if !is_load => {
                        // Since mov(mem64, imm32) sign extends, as_i64() makes sure
                        // we split when the extended value is different.
                        if !value.special_const_p() || imm_num_bits(value.as_i64()) > 32 {
                            asm.load(iterator.map_opnd(*opnd))
                        } else {
                            Opnd::UImm(value.as_u64())
                        }
                    }
                    _ => iterator.map_opnd(*opnd),
                };
            }

            // We are replacing instructions here so we know they are already
            // being used. It is okay not to use their output here.
            #[allow(unused_must_use)]
            match &mut insn {
                Insn::Add { left, right, out } |
                Insn::Sub { left, right, out } |
                Insn::Mul { left, right, out } |
                Insn::And { left, right, out } |
                Insn::Or { left, right, out } |
                Insn::Xor { left, right, out } => {
                    match (&left, &right, iterator.peek()) {
                        // Merge this insn, e.g. `add REG, right -> out`, and `mov REG, out` if possible
                        (Opnd::Reg(_), Opnd::UImm(value), Some(Insn::Mov { dest, src }))
                        if out == src && left == dest && live_ranges[index] == index + 1 && uimm_num_bits(*value) <= 32 => {
                            *out = *dest;
                            asm.push_insn(insn);
                            iterator.map_insn_index(&mut asm);
                            iterator.next_unmapped(); // Pop merged Insn::Mov
                        }
                        (Opnd::Reg(_), Opnd::Reg(_), Some(Insn::Mov { dest, src }))
                        if out == src && live_ranges[index] == index + 1 && {
                            // We want to do `dest == left`, but `left` has already gone
                            // through lower_stack_opnd() while `dest` has not. So we
                            // lower `dest` before comparing.
                            let lowered_dest = if let Opnd::Stack { .. } = dest {
                                asm.lower_stack_opnd(dest)
                            } else {
                                *dest
                            };
                            lowered_dest == *left
                        } => {
                            *out = *dest;
                            asm.push_insn(insn);
                            iterator.map_insn_index(&mut asm);
                            iterator.next_unmapped(); // Pop merged Insn::Mov
                        }
                        _ => {
                            match (unmapped_opnds[0], unmapped_opnds[1]) {
                                (Opnd::Mem(_), Opnd::Mem(_)) => {
                                    *left = asm.load(*left);
                                    *right = asm.load(*right);
                                },
                                (Opnd::Mem(_), Opnd::UImm(_) | Opnd::Imm(_)) => {
                                    *left = asm.load(*left);
                                },
                                // Instruction output whose live range spans beyond this instruction
                                (Opnd::InsnOut { idx, .. }, _) => {
                                    if live_ranges[idx] > index {
                                        *left = asm.load(*left);
                                    }
                                },
                                // We have to load memory operands to avoid corrupting them
                                (Opnd::Mem(_) | Opnd::Reg(_), _) => {
                                    *left = asm.load(*left);
                                },
                                _ => {}
                            };

                            *out = asm.next_opnd_out(Opnd::match_num_bits(&[*left, *right]));
                            asm.push_insn(insn);
                        }
                    }
                },
                Insn::Cmp { left, right } => {
                    // Replace `cmp REG, 0` (4 bytes) with `test REG, REG` (3 bytes)
                    // when next IR is `je`, `jne`, `csel_e`, or `csel_ne`
                    match (&left, &right, iterator.peek()) {
                        (Opnd::InsnOut { .. },
                         Opnd::UImm(0) | Opnd::Imm(0),
                         Some(Insn::Je(_) | Insn::Jne(_) | Insn::CSelE { .. } | Insn::CSelNE { .. })) => {
                            asm.push_insn(Insn::Test { left: *left, right: *left });
                        }
                        _ => {
                            if let (Opnd::Mem(_), Opnd::Mem(_)) = (&left, &right) {
                                let loaded = asm.load(*right);
                                *right = loaded;
                            }
                            asm.push_insn(insn);
                        }
                    }
                },
                Insn::Test { left, right } => {
                    if let (Opnd::Mem(_), Opnd::Mem(_)) = (&left, &right) {
                        let loaded = asm.load(*right);
                        *right = loaded;
                    }
                    asm.push_insn(insn);
                },
                // These instructions modify their input operand in-place, so we
                // may need to load the input value to preserve it
                Insn::LShift { opnd, shift, out } |
                Insn::RShift { opnd, shift, out } |
                Insn::URShift { opnd, shift, out } => {
                    match (&unmapped_opnds[0], &unmapped_opnds[1]) {
                        // Instruction output whose live range spans beyond this instruction
                        (Opnd::InsnOut { idx, .. }, _) => {
                            if live_ranges[*idx] > index {
                                *opnd = asm.load(*opnd);
                            }
                        },
                        // We have to load memory operands to avoid corrupting them
                        (Opnd::Mem(_) | Opnd::Reg(_), _) => {
                            *opnd = asm.load(*opnd);
                        },
                        _ => {}
                    };

                    *out = asm.next_opnd_out(Opnd::match_num_bits(&[*opnd, *shift]));
                    asm.push_insn(insn);
                },
                Insn::CSelZ { truthy, falsy, out } |
                Insn::CSelNZ { truthy, falsy, out } |
                Insn::CSelE { truthy, falsy, out } |
                Insn::CSelNE { truthy, falsy, out } |
                Insn::CSelL { truthy, falsy, out } |
                Insn::CSelLE { truthy, falsy, out } |
                Insn::CSelG { truthy, falsy, out } |
                Insn::CSelGE { truthy, falsy, out } => {
                    match unmapped_opnds[0] {
                        // If we have an instruction output whose live range
                        // spans beyond this instruction, we have to load it.
                        Opnd::InsnOut { idx, .. } => {
                            if live_ranges[idx] > index {
                                *truthy = asm.load(*truthy);
                            }
                        },
                        Opnd::UImm(_) | Opnd::Imm(_) => {
                            *truthy = asm.load(*truthy);
                        },
                        // Opnd::Value could have already been split
                        Opnd::Value(_) if !matches!(truthy, Opnd::InsnOut { .. }) => {
                            *truthy = asm.load(*truthy);
                        },
                        _ => {}
                    };

                    match falsy {
                        Opnd::UImm(_) | Opnd::Imm(_) => {
                            *falsy = asm.load(*falsy);
                        },
                        _ => {}
                    };

                    *out = asm.next_opnd_out(Opnd::match_num_bits(&[*truthy, *falsy]));
                    asm.push_insn(insn);
                },
                Insn::Mov { dest, src } | Insn::Store { dest, src } => {
                    match (&dest, &src) {
                        (Opnd::Mem(_), Opnd::Mem(_)) => {
                            // We load opnd1 because for mov, opnd0 is the output
                            let opnd1 = asm.load(*src);
                            asm.mov(*dest, opnd1);
                        },
                        (Opnd::Mem(_), Opnd::UImm(value)) => {
                            // 32-bit values will be sign-extended
                            if imm_num_bits(*value as i64) > 32 {
                                let opnd1 = asm.load(*src);
                                asm.mov(*dest, opnd1);
                            } else {
                                asm.mov(*dest, *src);
                            }
                        },
                        (Opnd::Mem(_), Opnd::Imm(value)) => {
                            if imm_num_bits(*value) > 32 {
                                let opnd1 = asm.load(*src);
                                asm.mov(*dest, opnd1);
                            } else {
                                asm.mov(*dest, *src);
                            }
                        },
                        _ => {
                            asm.mov(*dest, *src);
                        }
                    }
                },
                Insn::Not { opnd, .. } => {
                    let opnd0 = match unmapped_opnds[0] {
                        // If we have an instruction output whose live range
                        // spans beyond this instruction, we have to load it.
                        Opnd::InsnOut { idx, .. } => {
                            if live_ranges[idx] > index {
                                asm.load(*opnd)
                            } else {
                                *opnd
                            }
                        },
                        // We have to load memory and register operands to avoid
                        // corrupting them.
                        Opnd::Mem(_) | Opnd::Reg(_) => {
                            asm.load(*opnd)
                        },
                        // Otherwise we can just reuse the existing operand.
                        _ => *opnd
                    };

                    asm.not(opnd0);
                },
                Insn::CCall { opnds, fptr, .. } => {
                    assert!(opnds.len() <= C_ARG_OPNDS.len());

                    // Load each operand into the corresponding argument
                    // register.
                    for (idx, opnd) in opnds.into_iter().enumerate() {
                        asm.load_into(Opnd::c_arg(C_ARG_OPNDS[idx]), *opnd);
                    }

                    // Now we push the CCall without any arguments so that it
                    // just performs the call.
                    asm.ccall(*fptr, vec![]);
                },
                Insn::Lea { .. } => {
                    // Merge `lea` and `mov` into a single `lea` when possible
                    match (&insn, iterator.peek()) {
                        (Insn::Lea { opnd, out }, Some(Insn::Mov { dest: Opnd::Reg(reg), src }))
                        if matches!(out, Opnd::InsnOut { .. }) && out == src && live_ranges[index] == index + 1 => {
                            asm.push_insn(Insn::Lea { opnd: *opnd, out: Opnd::Reg(*reg) });
                            iterator.map_insn_index(&mut asm);
                            iterator.next_unmapped(); // Pop merged Insn::Mov
                        }
                        _ => asm.push_insn(insn),
                    }
                },
                _ => {
                    if insn.out_opnd().is_some() {
                        let out_num_bits = Opnd::match_num_bits_iter(insn.opnd_iter());
                        let out = insn.out_opnd_mut().unwrap();
                        *out = asm.next_opnd_out(out_num_bits);
                    }

                    asm.push_insn(insn);
                }
            };

            iterator.map_insn_index(&mut asm);
        }

        asm
    }

    /// Emit platform-specific machine code
    pub fn x86_emit(&mut self, cb: &mut CodeBlock, ocb: &mut Option<&mut OutlinedCb>) -> Option<Vec<u32>>
    {
        /// For some instructions, we want to be able to lower a 64-bit operand
        /// without requiring more registers to be available in the register
        /// allocator. So we just use the SCRATCH0 register temporarily to hold
        /// the value before we immediately use it.
        fn emit_64bit_immediate(cb: &mut CodeBlock, opnd: &Opnd) -> X86Opnd {
            match opnd {
                Opnd::Imm(value) => {
                    // 32-bit values will be sign-extended
                    if imm_num_bits(*value) > 32 {
                        mov(cb, Assembler::SCRATCH0, opnd.into());
                        Assembler::SCRATCH0
                    } else {
                        opnd.into()
                    }
                },
                Opnd::UImm(value) => {
                    // 32-bit values will be sign-extended
                    if imm_num_bits(*value as i64) > 32 {
                        mov(cb, Assembler::SCRATCH0, opnd.into());
                        Assembler::SCRATCH0
                    } else {
                        opnd.into()
                    }
                },
                _ => opnd.into()
            }
        }

        /// Compile a side exit if Target::SideExit is given.
        fn compile_side_exit(
            target: Target,
            asm: &mut Assembler,
            ocb: &mut Option<&mut OutlinedCb>,
        ) -> Option<Target> {
            if let Target::SideExit { counter, context } = target {
                let side_exit = asm.get_side_exit(&context.unwrap(), Some(counter), ocb.as_mut().unwrap());
                Some(Target::SideExitPtr(side_exit?))
            } else {
                Some(target)
            }
        }

        fn emit_csel(
            cb: &mut CodeBlock,
            truthy: Opnd,
            falsy: Opnd,
            out: Opnd,
            cmov_fn: fn(&mut CodeBlock, X86Opnd, X86Opnd),
            cmov_neg: fn(&mut CodeBlock, X86Opnd, X86Opnd)){

            // Assert that output is a register
            out.unwrap_reg();

            // If the truthy value is a memory operand
            if let Opnd::Mem(_) = truthy {
                if out != falsy {
                    mov(cb, out.into(), falsy.into());
                }

                cmov_fn(cb, out.into(), truthy.into());
            } else {
                if out != truthy {
                    mov(cb, out.into(), truthy.into());
                }

                cmov_neg(cb, out.into(), falsy.into());
            }
        }

        //dbg!(&self.insns);

        // List of GC offsets
        let mut gc_offsets: Vec<u32> = Vec::new();

        // Buffered list of PosMarker callbacks to fire if codegen is successful
        let mut pos_markers: Vec<(usize, CodePtr)> = vec![];

        // For each instruction
        let start_write_pos = cb.get_write_pos();
        let mut insn_idx: usize = 0;
        while let Some(insn) = self.insns.get(insn_idx) {
            let src_ptr = cb.get_write_ptr();
            let had_dropped_bytes = cb.has_dropped_bytes();
            let old_label_state = cb.get_label_state();
            let mut insn_gc_offsets: Vec<u32> = Vec::new();

            match insn {
                Insn::Comment(text) => {
                    cb.add_comment(text);
                },

                // Write the label at the current position
                Insn::Label(target) => {
                    cb.write_label(target.unwrap_label_idx());
                },

                // Report back the current position in the generated code
                Insn::PosMarker(..) => {
                    pos_markers.push((insn_idx, cb.get_write_ptr()));
                },

                Insn::BakeString(text) => {
                    for byte in text.as_bytes() {
                        cb.write_byte(*byte);
                    }

                    // Add a null-terminator byte for safety (in case we pass
                    // this to C code)
                    cb.write_byte(0);
                },

                // Set up RBP to work with frame pointer unwinding
                // (e.g. with Linux `perf record --call-graph fp`)
                Insn::FrameSetup => {
                    if get_option!(frame_pointer) {
                        push(cb, RBP);
                        mov(cb, RBP, RSP);
                        push(cb, RBP);
                    }
                },
                Insn::FrameTeardown => {
                    if get_option!(frame_pointer) {
                        pop(cb, RBP);
                        pop(cb, RBP);
                    }
                },

                Insn::Add { left, right, .. } => {
                    let opnd1 = emit_64bit_immediate(cb, right);
                    add(cb, left.into(), opnd1);
                },

                Insn::Sub { left, right, .. } => {
                    let opnd1 = emit_64bit_immediate(cb, right);
                    sub(cb, left.into(), opnd1);
                },

                Insn::Mul { left, right, .. } => {
                    let opnd1 = emit_64bit_immediate(cb, right);
                    imul(cb, left.into(), opnd1);
                },

                Insn::And { left, right, .. } => {
                    let opnd1 = emit_64bit_immediate(cb, right);
                    and(cb, left.into(), opnd1);
                },

                Insn::Or { left, right, .. } => {
                    let opnd1 = emit_64bit_immediate(cb, right);
                    or(cb, left.into(), opnd1);
                },

                Insn::Xor { left, right, .. } => {
                    let opnd1 = emit_64bit_immediate(cb, right);
                    xor(cb, left.into(), opnd1);
                },

                Insn::Not { opnd, .. } => {
                    not(cb, opnd.into());
                },

                Insn::LShift { opnd, shift , ..} => {
                    shl(cb, opnd.into(), shift.into())
                },

                Insn::RShift { opnd, shift , ..} => {
                    sar(cb, opnd.into(), shift.into())
                },

                Insn::URShift { opnd, shift, .. } => {
                    shr(cb, opnd.into(), shift.into())
                },

                Insn::Store { dest, src } => {
                    mov(cb, dest.into(), src.into());
                },

                // This assumes only load instructions can contain references to GC'd Value operands
                Insn::Load { opnd, out } |
                Insn::LoadInto { dest: out, opnd } => {
                    match opnd {
                        Opnd::Value(val) if val.heap_object_p() => {
                            // Using movabs because mov might write value in 32 bits
                            movabs(cb, out.into(), val.0 as _);
                            // The pointer immediate is encoded as the last part of the mov written out
                            let ptr_offset: u32 = (cb.get_write_pos() as u32) - (SIZEOF_VALUE as u32);
                            insn_gc_offsets.push(ptr_offset);
                        }
                        _ => mov(cb, out.into(), opnd.into())
                    }
                },

                Insn::LoadSExt { opnd, out } => {
                    movsx(cb, out.into(), opnd.into());
                },

                Insn::Mov { dest, src } => {
                    mov(cb, dest.into(), src.into());
                },

                // Load effective address
                Insn::Lea { opnd, out } => {
                    lea(cb, out.into(), opnd.into());
                },

                // Load address of jump target
                Insn::LeaJumpTarget { target, out } => {
                    if let Target::Label(label_idx) = target {
                        // Set output to the raw address of the label
                        cb.label_ref(*label_idx, 7, |cb, src_addr, dst_addr| {
                            let disp = dst_addr - src_addr;
                            lea(cb, Self::SCRATCH0, mem_opnd(8, RIP, disp.try_into().unwrap()));
                        });

                        mov(cb, out.into(), Self::SCRATCH0);
                    } else {
                        // Set output to the jump target's raw address
                        let target_code = target.unwrap_code_ptr();
                        let target_addr = target_code.raw_addr(cb).as_u64();
                        // Constant encoded length important for patching
                        movabs(cb, out.into(), target_addr);
                    }
                },

                // Push and pop to/from the C stack
                Insn::CPush(opnd) => {
                    push(cb, opnd.into());
                },
                Insn::CPop { out } => {
                    pop(cb, out.into());
                },
                Insn::CPopInto(opnd) => {
                    pop(cb, opnd.into());
                },

                // Push and pop to the C stack all caller-save registers and the
                // flags
                Insn::CPushAll => {
                    let regs = Assembler::get_caller_save_regs();

                    for reg in regs {
                        push(cb, X86Opnd::Reg(reg));
                    }
                    pushfq(cb);
                },
                Insn::CPopAll => {
                    let regs = Assembler::get_caller_save_regs();

                    popfq(cb);
                    for reg in regs.into_iter().rev() {
                        pop(cb, X86Opnd::Reg(reg));
                    }
                },

                // C function call
                Insn::CCall { fptr, .. } => {
                    call_ptr(cb, RAX, *fptr);
                },

                Insn::CRet(opnd) => {
                    // TODO: bias allocation towards return register
                    if *opnd != Opnd::Reg(C_RET_REG) {
                        mov(cb, RAX, opnd.into());
                    }

                    ret(cb);
                },

                // Compare
                Insn::Cmp { left, right } => {
                    let num_bits = match right {
                        Opnd::Imm(value) => Some(imm_num_bits(*value)),
                        Opnd::UImm(value) => Some(uimm_num_bits(*value)),
                        _ => None
                    };

                    // If the immediate is less than 64 bits (like 32, 16, 8), and the operand
                    // sizes match, then we can represent it as an immediate in the instruction
                    // without moving it to a register first.
                    // IOW, 64 bit immediates must always be moved to a register
                    // before comparisons, where other sizes may be encoded
                    // directly in the instruction.
                    if num_bits.is_some() && left.num_bits() == num_bits && num_bits.unwrap() < 64 {
                        cmp(cb, left.into(), right.into());
                    } else {
                        let emitted = emit_64bit_immediate(cb, right);
                        cmp(cb, left.into(), emitted);
                    }
                }

                // Test and set flags
                Insn::Test { left, right } => {
                    let emitted = emit_64bit_immediate(cb, right);
                    test(cb, left.into(), emitted);
                }

                Insn::JmpOpnd(opnd) => {
                    jmp_rm(cb, opnd.into());
                }

                // Conditional jump to a label
                Insn::Jmp(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => jmp_ptr(cb, code_ptr),
                        Target::Label(label_idx) => jmp_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                }

                Insn::Je(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => je_ptr(cb, code_ptr),
                        Target::Label(label_idx) => je_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                }

                Insn::Jne(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => jne_ptr(cb, code_ptr),
                        Target::Label(label_idx) => jne_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                }

                Insn::Jl(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => jl_ptr(cb, code_ptr),
                        Target::Label(label_idx) => jl_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                },

                Insn::Jg(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => jg_ptr(cb, code_ptr),
                        Target::Label(label_idx) => jg_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                },

                Insn::Jge(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => jge_ptr(cb, code_ptr),
                        Target::Label(label_idx) => jge_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                },

                Insn::Jbe(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => jbe_ptr(cb, code_ptr),
                        Target::Label(label_idx) => jbe_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                },

                Insn::Jb(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => jb_ptr(cb, code_ptr),
                        Target::Label(label_idx) => jb_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                },

                Insn::Jz(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => jz_ptr(cb, code_ptr),
                        Target::Label(label_idx) => jz_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                }

                Insn::Jnz(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => jnz_ptr(cb, code_ptr),
                        Target::Label(label_idx) => jnz_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                }

                Insn::Jo(target) |
                Insn::JoMul(target) => {
                    match compile_side_exit(*target, self, ocb)? {
                        Target::CodePtr(code_ptr) | Target::SideExitPtr(code_ptr) => jo_ptr(cb, code_ptr),
                        Target::Label(label_idx) => jo_label(cb, label_idx),
                        Target::SideExit { .. } => unreachable!("Target::SideExit should have been compiled by compile_side_exit"),
                    }
                }

                Insn::Joz(..) | Insn::Jonz(..) => unreachable!("Joz/Jonz should be unused for now"),

                // Atomically increment a counter at a given memory location
                Insn::IncrCounter { mem, value } => {
                    assert!(matches!(mem, Opnd::Mem(_)));
                    assert!(matches!(value, Opnd::UImm(_) | Opnd::Imm(_) ) );
                    write_lock_prefix(cb);
                    add(cb, mem.into(), value.into());
                },

                Insn::Breakpoint => int3(cb),

                Insn::CSelZ { truthy, falsy, out } => {
                    emit_csel(cb, *truthy, *falsy, *out, cmovz, cmovnz);
                },
                Insn::CSelNZ { truthy, falsy, out } => {
                    emit_csel(cb, *truthy, *falsy, *out, cmovnz, cmovz);
                },
                Insn::CSelE { truthy, falsy, out } => {
                    emit_csel(cb, *truthy, *falsy, *out, cmove, cmovne);
                },
                Insn::CSelNE { truthy, falsy, out } => {
                    emit_csel(cb, *truthy, *falsy, *out, cmovne, cmove);
                },
                Insn::CSelL { truthy, falsy, out } => {
                    emit_csel(cb, *truthy, *falsy, *out, cmovl, cmovge);
                },
                Insn::CSelLE { truthy, falsy, out } => {
                    emit_csel(cb, *truthy, *falsy, *out, cmovle, cmovg);
                },
                Insn::CSelG { truthy, falsy, out } => {
                    emit_csel(cb, *truthy, *falsy, *out, cmovg, cmovle);
                },
                Insn::CSelGE { truthy, falsy, out } => {
                    emit_csel(cb, *truthy, *falsy, *out, cmovge, cmovl);
                }
                Insn::LiveReg { .. } => (), // just a reg alloc signal, no code
                Insn::PadInvalPatch => {
                    let code_size = cb.get_write_pos().saturating_sub(std::cmp::max(start_write_pos, cb.page_start_pos()));
                    if code_size < cb.jmp_ptr_bytes() {
                        nop(cb, (cb.jmp_ptr_bytes() - code_size) as u32);
                    }
                }
            };

            // On failure, jump to the next page and retry the current insn
            if !had_dropped_bytes && cb.has_dropped_bytes() && cb.next_page(src_ptr, jmp_ptr) {
                // Reset cb states before retrying the current Insn
                cb.set_label_state(old_label_state);
            } else {
                insn_idx += 1;
                gc_offsets.append(&mut insn_gc_offsets);
            }
        }

        // Error if we couldn't write out everything
        if cb.has_dropped_bytes() {
            return None
        } else {
            // No bytes dropped, so the pos markers point to valid code
            for (insn_idx, pos) in pos_markers {
                if let Insn::PosMarker(callback) = self.insns.get(insn_idx).unwrap() {
                    callback(pos, &cb);
                } else {
                    panic!("non-PosMarker in pos_markers insn_idx={insn_idx} {self:?}");
                }
            }

            return Some(gc_offsets)
        }
    }

    /// Optimize and compile the stored instructions
    pub fn compile_with_regs(self, cb: &mut CodeBlock, ocb: Option<&mut OutlinedCb>, regs: Vec<Reg>) -> Option<(CodePtr, Vec<u32>)> {
        let asm = self.x86_split();
        let mut asm = asm.alloc_regs(regs);

        // Create label instances in the code block
        for (idx, name) in asm.label_names.iter().enumerate() {
            let label_idx = cb.new_label(name.to_string());
            assert!(label_idx == idx);
        }

        let mut ocb = ocb; // for &mut
        let start_ptr = cb.get_write_ptr();
        let gc_offsets = asm.x86_emit(cb, &mut ocb);

        if let (Some(gc_offsets), false) = (gc_offsets, cb.has_dropped_bytes()) {
            cb.link_labels();

            Some((start_ptr, gc_offsets))
        } else {
            cb.clear_labels();

            None
        }
    }
}

#[cfg(test)]
mod tests {
    use crate::disasm::assert_disasm;
    #[cfg(feature = "disasm")]
    use crate::disasm::{unindent, disasm_addr_range};

    use super::*;

    fn setup_asm() -> (Assembler, CodeBlock) {
        (Assembler::new(0), CodeBlock::new_dummy(1024))
    }

    #[test]
    fn test_emit_add_lt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        let _ = asm.add(Opnd::Reg(RAX_REG), Opnd::UImm(0xFF));
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4889c04881c0ff000000");
    }

    #[test]
    fn test_emit_add_gt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        let _ = asm.add(Opnd::Reg(RAX_REG), Opnd::UImm(0xFFFF_FFFF_FFFF));
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4889c049bbffffffffffff00004c01d8");
    }

    #[test]
    fn test_emit_and_lt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        let _ = asm.and(Opnd::Reg(RAX_REG), Opnd::UImm(0xFF));
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4889c04881e0ff000000");
    }

    #[test]
    fn test_emit_and_gt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        let _ = asm.and(Opnd::Reg(RAX_REG), Opnd::UImm(0xFFFF_FFFF_FFFF));
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4889c049bbffffffffffff00004c21d8");
    }

    #[test]
    fn test_emit_cmp_lt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        asm.cmp(Opnd::Reg(RAX_REG), Opnd::UImm(0xFF));
        asm.compile_with_num_regs(&mut cb, 0);

        assert_eq!(format!("{:x}", cb), "4881f8ff000000");
    }

    #[test]
    fn test_emit_cmp_gt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        asm.cmp(Opnd::Reg(RAX_REG), Opnd::UImm(0xFFFF_FFFF_FFFF));
        asm.compile_with_num_regs(&mut cb, 0);

        assert_eq!(format!("{:x}", cb), "49bbffffffffffff00004c39d8");
    }

    #[test]
    fn test_emit_cmp_mem_16_bits_with_imm_16() {
        let (mut asm, mut cb) = setup_asm();

        let shape_opnd = Opnd::mem(16, Opnd::Reg(RAX_REG), 6);

        asm.cmp(shape_opnd, Opnd::UImm(0xF000));
        asm.compile_with_num_regs(&mut cb, 0);

        assert_eq!(format!("{:x}", cb), "6681780600f0");
    }

    #[test]
    fn test_emit_cmp_mem_32_bits_with_imm_32() {
        let (mut asm, mut cb) = setup_asm();

        let shape_opnd = Opnd::mem(32, Opnd::Reg(RAX_REG), 4);

        asm.cmp(shape_opnd, Opnd::UImm(0xF000_0000));
        asm.compile_with_num_regs(&mut cb, 0);

        assert_eq!(format!("{:x}", cb), "817804000000f0");
    }

    #[test]
    fn test_emit_or_lt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        let _ = asm.or(Opnd::Reg(RAX_REG), Opnd::UImm(0xFF));
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4889c04881c8ff000000");
    }

    #[test]
    fn test_emit_or_gt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        let _ = asm.or(Opnd::Reg(RAX_REG), Opnd::UImm(0xFFFF_FFFF_FFFF));
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4889c049bbffffffffffff00004c09d8");
    }

    #[test]
    fn test_emit_sub_lt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        let _ = asm.sub(Opnd::Reg(RAX_REG), Opnd::UImm(0xFF));
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4889c04881e8ff000000");
    }

    #[test]
    fn test_emit_sub_gt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        let _ = asm.sub(Opnd::Reg(RAX_REG), Opnd::UImm(0xFFFF_FFFF_FFFF));
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4889c049bbffffffffffff00004c29d8");
    }

    #[test]
    fn test_emit_test_lt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        asm.test(Opnd::Reg(RAX_REG), Opnd::UImm(0xFF));
        asm.compile_with_num_regs(&mut cb, 0);

        assert_eq!(format!("{:x}", cb), "f6c0ff");
    }

    #[test]
    fn test_emit_test_gt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        asm.test(Opnd::Reg(RAX_REG), Opnd::UImm(0xFFFF_FFFF_FFFF));
        asm.compile_with_num_regs(&mut cb, 0);

        assert_eq!(format!("{:x}", cb), "49bbffffffffffff00004c85d8");
    }

    #[test]
    fn test_emit_xor_lt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        let _ = asm.xor(Opnd::Reg(RAX_REG), Opnd::UImm(0xFF));
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4889c04881f0ff000000");
    }

    #[test]
    fn test_emit_xor_gt_32_bits() {
        let (mut asm, mut cb) = setup_asm();

        let _ = asm.xor(Opnd::Reg(RAX_REG), Opnd::UImm(0xFFFF_FFFF_FFFF));
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4889c049bbffffffffffff00004c31d8");
    }

    #[test]
    fn test_merge_lea_reg() {
        let (mut asm, mut cb) = setup_asm();

        let sp = asm.lea(Opnd::mem(64, SP, 8));
        asm.mov(SP, sp); // should be merged to lea
        asm.compile_with_num_regs(&mut cb, 1);

        assert_disasm!(cb, "488d5b08", {"
            0x0: lea rbx, [rbx + 8]
        "});
    }

    #[test]
    fn test_merge_lea_mem() {
        let (mut asm, mut cb) = setup_asm();

        let sp = asm.lea(Opnd::mem(64, SP, 8));
        asm.mov(Opnd::mem(64, SP, 0), sp); // should NOT be merged to lea
        asm.compile_with_num_regs(&mut cb, 1);

        assert_disasm!(cb, "488d4308488903", {"
            0x0: lea rax, [rbx + 8]
            0x4: mov qword ptr [rbx], rax
        "});
    }

    #[test]
    fn test_replace_cmp_0() {
        let (mut asm, mut cb) = setup_asm();

        let val = asm.load(Opnd::mem(64, SP, 8));
        asm.cmp(val, 0.into());
        let result = asm.csel_e(Qtrue.into(), Qfalse.into());
        asm.mov(Opnd::Reg(RAX_REG), result);
        asm.compile_with_num_regs(&mut cb, 2);

        assert_eq!(format!("{:x}", cb), "488b43084885c0b814000000b900000000480f45c14889c0");
    }

    #[test]
    fn test_merge_add_mov() {
        let (mut asm, mut cb) = setup_asm();

        let sp = asm.add(CFP, Opnd::UImm(0x40));
        asm.mov(CFP, sp); // should be merged to add
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4983c540");
    }

    #[test]
    fn test_merge_sub_mov() {
        let (mut asm, mut cb) = setup_asm();

        let sp = asm.sub(CFP, Opnd::UImm(0x40));
        asm.mov(CFP, sp); // should be merged to add
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4983ed40");
    }

    #[test]
    fn test_merge_and_mov() {
        let (mut asm, mut cb) = setup_asm();

        let sp = asm.and(CFP, Opnd::UImm(0x40));
        asm.mov(CFP, sp); // should be merged to add
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4983e540");
    }

    #[test]
    fn test_merge_or_mov() {
        let (mut asm, mut cb) = setup_asm();

        let sp = asm.or(CFP, Opnd::UImm(0x40));
        asm.mov(CFP, sp); // should be merged to add
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4983cd40");
    }

    #[test]
    fn test_merge_xor_mov() {
        let (mut asm, mut cb) = setup_asm();

        let sp = asm.xor(CFP, Opnd::UImm(0x40));
        asm.mov(CFP, sp); // should be merged to add
        asm.compile_with_num_regs(&mut cb, 1);

        assert_eq!(format!("{:x}", cb), "4983f540");
    }

    #[test]
    fn test_reorder_c_args_no_cycle() {
        let (mut asm, mut cb) = setup_asm();

        asm.ccall(0 as _, vec![
            C_ARG_OPNDS[0], // mov rdi, rdi (optimized away)
            C_ARG_OPNDS[1], // mov rsi, rsi (optimized away)
        ]);
        asm.compile_with_num_regs(&mut cb, 0);

        assert_disasm!(cb, "b800000000ffd0", {"
            0x0: mov eax, 0
            0x5: call rax
        "});
    }

    #[test]
    fn test_reorder_c_args_single_cycle() {
        let (mut asm, mut cb) = setup_asm();

        // rdi and rsi form a cycle
        asm.ccall(0 as _, vec![
            C_ARG_OPNDS[1], // mov rdi, rsi
            C_ARG_OPNDS[0], // mov rsi, rdi
            C_ARG_OPNDS[2], // mov rdx, rdx (optimized away)
        ]);
        asm.compile_with_num_regs(&mut cb, 0);

        assert_disasm!(cb, "4989f34889fe4c89dfb800000000ffd0", {"
            0x0: mov r11, rsi
            0x3: mov rsi, rdi
            0x6: mov rdi, r11
            0x9: mov eax, 0
            0xe: call rax
        "});
    }

    #[test]
    fn test_reorder_c_args_two_cycles() {
        let (mut asm, mut cb) = setup_asm();

        // rdi and rsi form a cycle, and rdx and rcx form another cycle
        asm.ccall(0 as _, vec![
            C_ARG_OPNDS[1], // mov rdi, rsi
            C_ARG_OPNDS[0], // mov rsi, rdi
            C_ARG_OPNDS[3], // mov rdx, rcx
            C_ARG_OPNDS[2], // mov rcx, rdx
        ]);
        asm.compile_with_num_regs(&mut cb, 0);

        assert_disasm!(cb, "4989f34889fe4c89df4989cb4889d14c89dab800000000ffd0", {"
            0x0: mov r11, rsi
            0x3: mov rsi, rdi
            0x6: mov rdi, r11
            0x9: mov r11, rcx
            0xc: mov rcx, rdx
            0xf: mov rdx, r11
            0x12: mov eax, 0
            0x17: call rax
        "});
    }

    #[test]
    fn test_reorder_c_args_large_cycle() {
        let (mut asm, mut cb) = setup_asm();

        // rdi, rsi, and rdx form a cycle
        asm.ccall(0 as _, vec![
            C_ARG_OPNDS[1], // mov rdi, rsi
            C_ARG_OPNDS[2], // mov rsi, rdx
            C_ARG_OPNDS[0], // mov rdx, rdi
        ]);
        asm.compile_with_num_regs(&mut cb, 0);

        assert_disasm!(cb, "4989f34889d64889fa4c89dfb800000000ffd0", {"
            0x0: mov r11, rsi
            0x3: mov rsi, rdx
            0x6: mov rdx, rdi
            0x9: mov rdi, r11
            0xc: mov eax, 0
            0x11: call rax
        "});
    }

    #[test]
    fn test_reorder_c_args_with_insn_out() {
        let (mut asm, mut cb) = setup_asm();

        let rax = asm.load(Opnd::UImm(1));
        let rcx = asm.load(Opnd::UImm(2));
        let rdx = asm.load(Opnd::UImm(3));
        // rcx and rdx form a cycle
        asm.ccall(0 as _, vec![
            rax, // mov rdi, rax
            rcx, // mov rsi, rcx
            rcx, // mov rdx, rcx
            rdx, // mov rcx, rdx
        ]);
        asm.compile_with_num_regs(&mut cb, 3);

        assert_disasm!(cb, "b801000000b902000000ba030000004889c74889ce4989cb4889d14c89dab800000000ffd0", {"
            0x0: mov eax, 1
            0x5: mov ecx, 2
            0xa: mov edx, 3
            0xf: mov rdi, rax
            0x12: mov rsi, rcx
            0x15: mov r11, rcx
            0x18: mov rcx, rdx
            0x1b: mov rdx, r11
            0x1e: mov eax, 0
            0x23: call rax
        "});
    }

    #[test]
    fn test_cmov_mem() {
        let (mut asm, mut cb) = setup_asm();

        let top = Opnd::mem(64, SP, 0);
        let ary_opnd = SP;
        let array_len_opnd = Opnd::mem(64, SP, 16);

        asm.cmp(array_len_opnd, 1.into());
        let elem_opnd = asm.csel_g(Opnd::mem(64, ary_opnd, 0), Qnil.into());
        asm.mov(top, elem_opnd);

        asm.compile_with_num_regs(&mut cb, 1);

        assert_disasm!(cb, "48837b1001b804000000480f4f03488903", {"
            0x0: cmp qword ptr [rbx + 0x10], 1
            0x5: mov eax, 4
            0xa: cmovg rax, qword ptr [rbx]
            0xe: mov qword ptr [rbx], rax
        "});
    }

    #[test]
    fn test_csel_split() {
        let (mut asm, mut cb) = setup_asm();

        let stack_top = Opnd::mem(64, SP, 0);
        let elem_opnd = asm.csel_ne(VALUE(0x7f22c88d1930).into(), Qnil.into());
        asm.mov(stack_top, elem_opnd);

        asm.compile_with_num_regs(&mut cb, 3);

        assert_disasm!(cb, "48b830198dc8227f0000b904000000480f44c1488903", {"
            0x0: movabs rax, 0x7f22c88d1930
            0xa: mov ecx, 4
            0xf: cmove rax, rcx
            0x13: mov qword ptr [rbx], rax
        "});
    }
}
